/*

  FDI to raw bit stream converter
  Copyright (c) 2001 by Toni Wilen <twilen@arabuusimiehet.com>
  FDI 2.0 support
  Copyright (c) 2003-2004 by Toni Wilen <twilen@arabuusimiehet.com>
      and Vincent Joguin

  FDI format created by Vincent "ApH" Joguin

  Tiny changes - function type fixes, multiple drives, addition of
  get_last_head and C++ callability - by Thomas Harte, 2001,
  T.Harte@excite.co.uk


  This program is free software; you can redistribute it and/or modify it
  under the terms of the GNU General Public License as published by the Free
  Software Foundation; either version 2 of the License, or (at your option)
  any later version.

  This program is distributed in the hope that it will be useful, but WITHOUT
  ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
  FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License for
  more details.

  You should have received a copy of the GNU General Public License along
  with this program; if not, write to the Free Software Foundation, Inc.,
  59 Temple Place - Suite 330, Boston, MA  02111-1307, USA

*/

#define STATIC_INLINE
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <stdint.h>

/* IF UAE */
/*#include "sysconfig.h"
#include "sysdeps.h"
#include "zfile.h"*/
/* ELSE */
//#include "types.h"
#define xmalloc malloc
#include "fdi2raw.h"

#include "ibm.h"

#undef DEBUG
#define VERBOSE
#undef VERBOSE

#include <assert.h>

#ifdef DEBUG
static char *datalog(uae_u8 *src, int len) {
        static char buf[1000];
        static int offset;
        int i = 0, offset2;

        offset2 = offset;
        buf[offset++] = '\'';
        while (len--) {
                sprintf(buf + offset, "%02.2X", src[i]);
                offset += 2;
                i++;
                if (i > 10)
                        break;
        }
        buf[offset++] = '\'';
        buf[offset++] = 0;
        if (offset >= 900)
                offset = 0;
        return buf + offset2;
}
#else
static char *datalog(uae_u8 *src, int len) { return ""; }
#endif

#define outlog pclog
#define debuglog pclog

static int fdi_allocated;
#ifdef DEBUG
static void fdi_free(void *p) {
        int size;
        if (!p)
                return;
        size = ((int *)p)[-1];
        fdi_allocated -= size;
        write_log("%d freed (%d)\n", size, fdi_allocated);
        free((int *)p - 1);
}
static void *fdi_malloc(int size) {
        void *p = xmalloc(size + sizeof(int));
        ((int *)p)[0] = size;
        fdi_allocated += size;
        write_log("%d allocated (%d)\n", size, fdi_allocated);
        return (int *)p + 1;
}
#else
#define fdi_free free
#define fdi_malloc xmalloc
#endif

#define MAX_SRC_BUFFER 4194304
#define MAX_DST_BUFFER 40000
#define MAX_MFM_SYNC_BUFFER 60000
#define MAX_TIMING_BUFFER 400000
#define MAX_TRACKS 166

struct fdi_cache {
        uae_u32 *avgp, *minp, *maxp;
        uae_u8 *idxp;
        int avg_free, idx_free, min_free, max_free;
        uae_u32 totalavg, pulses, maxidx, indexoffset;
        int weakbits;
        int lowlevel;
};

struct fdi {
        uae_u8 *track_src_buffer;
        uae_u8 *track_src;
        int track_src_len;
        uae_u8 *track_dst_buffer;
        uae_u8 *track_dst;
        uae_u16 *track_dst_buffer_timing;
        uae_u8 track_len;
        uae_u8 track_type;
        int current_track;
        int last_track;
        int last_head;
        int rotation_speed;
        int bit_rate;
        int disk_type;
        int write_protect;
        int err;
        uae_u8 header[2048];
        int track_offsets[MAX_TRACKS];
        FILE *file;
        int out;
        int mfmsync_offset;
        int *mfmsync_buffer;
        /* sector described only */
        int index_offset;
        int encoding_type;
        /* bit handling */
        int nextdrop;
        struct fdi_cache cache[MAX_TRACKS];
};

#define get_u32(x) ((((x)[0]) << 24) | (((x)[1]) << 16) | (((x)[2]) << 8) | ((x)[3]))
#define get_u24(x) ((((x)[0]) << 16) | (((x)[1]) << 8) | ((x)[2]))
STATIC_INLINE void put_u32(uae_u8 *d, uae_u32 v) {
        d[0] = v >> 24;
        d[1] = v >> 16;
        d[2] = v >> 8;
        d[3] = v;
}

struct node {
        uae_u16 v;
        struct node *left;
        struct node *right;
};
typedef struct node NODE;

static uae_u8 temp, temp2;

static uae_u8 *expand_tree(uae_u8 *stream, NODE *node) {
        if (temp & temp2) {
                fdi_free(node->left);
                node->left = 0;
                fdi_free(node->right);
                node->right = 0;
                temp2 >>= 1;
                if (!temp2) {
                        temp = *stream++;
                        temp2 = 0x80;
                }
                return stream;
        } else {
                uae_u8 *stream_temp;
                temp2 >>= 1;
                if (!temp2) {
                        temp = *stream++;
                        temp2 = 0x80;
                }
                node->left = fdi_malloc(sizeof(NODE));
                memset(node->left, 0, sizeof(NODE));
                stream_temp = expand_tree(stream, node->left);
                node->right = fdi_malloc(sizeof(NODE));
                memset(node->right, 0, sizeof(NODE));
                return expand_tree(stream_temp, node->right);
        }
}

static uae_u8 *values_tree8(uae_u8 *stream, NODE *node) {
        if (node->left == 0) {
                node->v = *stream++;
                return stream;
        } else {
                uae_u8 *stream_temp = values_tree8(stream, node->left);
                return values_tree8(stream_temp, node->right);
        }
}

static uae_u8 *values_tree16(uae_u8 *stream, NODE *node) {
        if (node->left == 0) {
                uae_u16 high_8_bits = (*stream++) << 8;
                node->v = high_8_bits | (*stream++);
                return stream;
        } else {
                uae_u8 *stream_temp = values_tree16(stream, node->left);
                return values_tree16(stream_temp, node->right);
        }
}

static void free_nodes(NODE *node) {
        if (node) {
                free_nodes(node->left);
                free_nodes(node->right);
                fdi_free(node);
        }
}

static uae_u32 sign_extend16(uae_u32 v) {
        if (v & 0x8000)
                v |= 0xffff0000;
        return v;
}

static uae_u32 sign_extend8(uae_u32 v) {
        if (v & 0x80)
                v |= 0xffffff00;
        return v;
}

static void fdi_decode(uae_u8 *stream, int size, uae_u8 *out) {
        int i;
        uae_u8 sign_extend, sixteen_bit, sub_stream_shift;
        NODE root;
        NODE *current_node;

        memset(out, 0, size * 4);
        sub_stream_shift = 1;
        while (sub_stream_shift) {

                // sub-stream header decode
                sign_extend = *stream++;
                sub_stream_shift = sign_extend & 0x7f;
                sign_extend &= 0x80;
                sixteen_bit = (*stream++) & 0x80;

                // huffman tree architecture decode
                temp = *stream++;
                temp2 = 0x80;
                stream = expand_tree(stream, &root);
                if (temp2 == 0x80)
                        stream--;

                // huffman output values	decode
                if (sixteen_bit)
                        stream = values_tree16(stream, &root);
                else
                        stream = values_tree8(stream, &root);

                // sub-stream data decode
                temp2 = 0;
                for (i = 0; i < size; i++) {
                        uae_u32 v;
                        uae_u8 decode = 1;
                        current_node = &root;
                        while (decode) {
                                if (current_node->left == 0) {
                                        decode = 0;
                                } else {
                                        temp2 >>= 1;
                                        if (!temp2) {
                                                temp2 = 0x80;
                                                temp = *stream++;
                                        }
                                        if (temp & temp2)
                                                current_node = current_node->right;
                                        else
                                                current_node = current_node->left;
                                }
                        }
                        v = ((uae_u32 *)out)[i];
                        if (sign_extend) {
                                if (sixteen_bit)
                                        v |= sign_extend16(current_node->v) << sub_stream_shift;
                                else
                                        v |= sign_extend8(current_node->v) << sub_stream_shift;
                        } else {
                                v |= current_node->v << sub_stream_shift;
                        }
                        ((uae_u32 *)out)[i] = v;
                }
                free_nodes(root.left);
                free_nodes(root.right);
        }
}

static int decode_raw_track(FDI *fdi) {
        int size = get_u32(fdi->track_src);
        memcpy(fdi->track_dst, fdi->track_src, (size + 7) >> 3);
        fdi->track_src += (size + 7) >> 3;
        return size;
}

/* unknown track */
static void zxx(FDI *fdi) {
        outlog("track %d: unknown track type 0x%02.2X\n", fdi->current_track, fdi->track_type);
        //	return -1;
}
/* unsupported track */
#if 0
static void zyy (FDI *fdi)
{
	outlog ("track %d: unsupported track type 0x%02.2X\n", fdi->current_track, fdi->track_type);
//	return -1;
}
#endif
/* empty track */
static void track_empty(FDI *fdi) {
        //	return 0;
}

/* unknown sector described type */
static void dxx(FDI *fdi) {
        outlog("\ntrack %d: unknown sector described type 0x%02.2X\n", fdi->current_track, fdi->track_type);
        fdi->err = 1;
}
/* unsupported sector described type */
#if 0
static void dyy (FDI *fdi)
{
	outlog ("\ntrack %d: unsupported sector described 0x%02.2X\n", fdi->current_track, fdi->track_type);
	fdi->err = 1;
}
#endif
/* add position of mfm sync bit */
static void add_mfm_sync_bit(FDI *fdi) {
        if (fdi->nextdrop) {
                fdi->nextdrop = 0;
                return;
        }
        fdi->mfmsync_buffer[fdi->mfmsync_offset++] = fdi->out;
        if (fdi->out == 0) {
                outlog("illegal position for mfm sync bit, offset=%d\n", fdi->out);
                fdi->err = 1;
        }
        if (fdi->mfmsync_offset >= MAX_MFM_SYNC_BUFFER) {
                fdi->mfmsync_offset = 0;
                outlog("mfmsync buffer overflow\n");
                fdi->err = 1;
        }
        fdi->out++;
}

#define BIT_BYTEOFFSET ((fdi->out) >> 3)
#define BIT_BITOFFSET (7 - ((fdi->out) & 7))

/* add one bit */
static void bit_add(FDI *fdi, int bit) {
        if (fdi->nextdrop) {
                fdi->nextdrop = 0;
                return;
        }
        fdi->track_dst[BIT_BYTEOFFSET] &= ~(1 << BIT_BITOFFSET);
        if (bit)
                fdi->track_dst[BIT_BYTEOFFSET] |= (1 << BIT_BITOFFSET);
        fdi->out++;
        if (fdi->out >= MAX_DST_BUFFER * 8) {
                outlog("destination buffer overflow\n");
                fdi->err = 1;
                fdi->out = 1;
        }
}
/* add bit and mfm sync bit */
static void bit_mfm_add(FDI *fdi, int bit) {
        add_mfm_sync_bit(fdi);
        bit_add(fdi, bit);
}
/* remove following bit */
static void bit_drop_next(FDI *fdi) {
        if (fdi->nextdrop > 0) {
                outlog("multiple bit_drop_next() called");
        } else if (fdi->nextdrop < 0) {
                fdi->nextdrop = 0;
                debuglog(":DNN:");
                return;
        }
        debuglog(":DN:");
        fdi->nextdrop = 1;
}

/* ignore next bit_drop_next() */
static void bit_dedrop(FDI *fdi) {
        if (fdi->nextdrop) {
                outlog("bit_drop_next called before bit_dedrop");
        }
        fdi->nextdrop = -1;
        debuglog(":BDD:");
}

/* add one byte */
static void byte_add(FDI *fdi, uae_u8 v) {
        int i;
        for (i = 7; i >= 0; i--)
                bit_add(fdi, v & (1 << i));
}
/* add one word */
static void word_add(FDI *fdi, uae_u16 v) {
        byte_add(fdi, (uae_u8)(v >> 8));
        byte_add(fdi, (uae_u8)v);
}
/* add one byte and mfm encode it */
static void byte_mfm_add(FDI *fdi, uae_u8 v) {
        int i;
        for (i = 7; i >= 0; i--)
                bit_mfm_add(fdi, v & (1 << i));
}
/* add multiple bytes and mfm encode them */
static void bytes_mfm_add(FDI *fdi, uae_u8 v, int len) {
        int i;
        for (i = 0; i < len; i++)
                byte_mfm_add(fdi, v);
}
/* add one mfm encoded word and re-mfm encode it */
static void word_post_mfm_add(FDI *fdi, uae_u16 v) {
        int i;
        for (i = 14; i >= 0; i -= 2)
                bit_mfm_add(fdi, v & (1 << i));
}

/* bit 0 */
static void s00(FDI *fdi) { bit_add(fdi, 0); }
/* bit 1*/
static void s01(FDI *fdi) { bit_add(fdi, 1); }
/* 4489 */
static void s02(FDI *fdi) { word_add(fdi, 0x4489); }
/* 5224 */
static void s03(FDI *fdi) { word_add(fdi, 0x5224); }
/* mfm sync bit */
static void s04(FDI *fdi) { add_mfm_sync_bit(fdi); }
/* RLE MFM-encoded data */
static void s08(FDI *fdi) {
        int bytes = *fdi->track_src++;
        uae_u8 byte = *fdi->track_src++;
        if (bytes == 0)
                bytes = 256;
        debuglog("s08:len=%d,data=%02.2X", bytes, byte);
        while (bytes--)
                byte_add(fdi, byte);
}
/* RLE MFM-decoded data */
static void s09(FDI *fdi) {
        int bytes = *fdi->track_src++;
        uae_u8 byte = *fdi->track_src++;
        if (bytes == 0)
                bytes = 256;
        bit_drop_next(fdi);
        debuglog("s09:len=%d,data=%02.2X", bytes, byte);
        while (bytes--)
                byte_mfm_add(fdi, byte);
}
/* MFM-encoded data */
static void s0a(FDI *fdi) {
        int i, bits = (fdi->track_src[0] << 8) | fdi->track_src[1];
        uae_u8 b;
        fdi->track_src += 2;
        debuglog("s0a:bits=%d,data=%s", bits, datalog(fdi->track_src, (bits + 7) / 8));
        while (bits >= 8) {
                byte_add(fdi, *fdi->track_src++);
                bits -= 8;
        }
        if (bits > 0) {
                i = 7;
                b = *fdi->track_src++;
                while (bits--) {
                        bit_add(fdi, b & (1 << i));
                        i--;
                }
        }
}
/* MFM-encoded data */
static void s0b(FDI *fdi) {
        int i, bits = ((fdi->track_src[0] << 8) | fdi->track_src[1]) + 65536;
        uae_u8 b;
        fdi->track_src += 2;
        debuglog("s0b:bits=%d,data=%s", bits, datalog(fdi->track_src, (bits + 7) / 8));
        while (bits >= 8) {
                byte_add(fdi, *fdi->track_src++);
                bits -= 8;
        }
        if (bits > 0) {
                i = 7;
                b = *fdi->track_src++;
                while (bits--) {
                        bit_add(fdi, b & (1 << i));
                        i--;
                }
        }
}
/* MFM-decoded data */
static void s0c(FDI *fdi) {
        int i, bits = (fdi->track_src[0] << 8) | fdi->track_src[1];
        uae_u8 b;
        fdi->track_src += 2;
        bit_drop_next(fdi);
        debuglog("s0c:bits=%d,data=%s", bits, datalog(fdi->track_src, (bits + 7) / 8));
        while (bits >= 8) {
                byte_mfm_add(fdi, *fdi->track_src++);
                bits -= 8;
        }
        if (bits > 0) {
                i = 7;
                b = *fdi->track_src++;
                while (bits--) {
                        bit_mfm_add(fdi, b & (1 << i));
                        i--;
                }
        }
}
/* MFM-decoded data */
static void s0d(FDI *fdi) {
        int i, bits = ((fdi->track_src[0] << 8) | fdi->track_src[1]) + 65536;
        uae_u8 b;
        fdi->track_src += 2;
        bit_drop_next(fdi);
        debuglog("s0d:bits=%d,data=%s", bits, datalog(fdi->track_src, (bits + 7) / 8));
        while (bits >= 8) {
                byte_mfm_add(fdi, *fdi->track_src++);
                bits -= 8;
        }
        if (bits > 0) {
                i = 7;
                b = *fdi->track_src++;
                while (bits--) {
                        bit_mfm_add(fdi, b & (1 << i));
                        i--;
                }
        }
}

/* ***** */
/* AMIGA */
/* ***** */

/* just for testing integrity of Amiga sectors */

/*static void rotateonebit (uae_u8 *start, uae_u8 *end, int shift)
{
        if (shift == 0)
                return;
        while (start <= end) {
                start[0] <<= shift;
                start[0] |= start[1] >> (8 - shift);
                start++;
        }
}*/

// static int check_offset;
/*static uae_u16 getmfmword (uae_u8 *mbuf)
{
        uae_u32 v;

        v = (mbuf[0] << 8) | (mbuf[1] << 0);
        if (check_offset == 0)
                return v;
        v <<= 8;
        v |= mbuf[2];
        v >>= check_offset;
        return v;
}*/

#define MFMMASK 0x55555555
/*static uae_u32 getmfmlong (uae_u8 * mbuf)
{
        return ((getmfmword (mbuf) << 16) | getmfmword (mbuf + 2)) & MFMMASK;
}*/

#if 0
static int amiga_check_track (FDI *fdi)
{
	int i, j, secwritten = 0;
	int fwlen = fdi->out / 8;
	int length = 2 * fwlen;
	int drvsec = 11;
	uae_u32 odd, even, chksum, id, dlong;
	uae_u8 *secdata;
	uae_u8 secbuf[544];
	uae_u8 bigmfmbuf[60000];
	uae_u8 *mbuf, *mbuf2, *mend;
	char sectable[22];
	uae_u8 *raw = fdi->track_dst_buffer;
	int slabel, off;
	int ok = 1;

	memset (bigmfmbuf, 0, sizeof (bigmfmbuf));
	mbuf = bigmfmbuf;
	check_offset = 0;
	for (i = 0; i < (fdi->out + 7) / 8; i++)
		*mbuf++ = raw[i];
	off = fdi->out & 7;
#if 1
	if (off > 0) {
		mbuf--;
		*mbuf &= ~((1 << (8 - off)) - 1);
	}
	j = 0;
	while (i < (fdi->out + 7) / 8 + 600) {
		*mbuf++ |= (raw[j] >> off) | ((raw[j + 1]) << (8 - off));
		j++;
		i++;
	}
#endif
	mbuf = bigmfmbuf;

	memset (sectable, 0, sizeof (sectable));
	//memcpy (mbuf + fwlen, mbuf, fwlen * sizeof (uae_u16));
	mend = bigmfmbuf + length;
	mend -= (4 + 16 + 8 + 512);

	while (secwritten < drvsec) {
		int trackoffs;

		for (;;) {
			rotateonebit (bigmfmbuf, mend, 1);
			if (getmfmword (mbuf) == 0)
				break;
			if (secwritten == 10) {
				mbuf[0] = 0x44;
				mbuf[1] = 0x89;
			}
//			check_offset++;
			if (check_offset > 7) {
				check_offset = 0;
				mbuf++;
				if (mbuf >= mend || *mbuf == 0)
					break;
			}
			if (getmfmword (mbuf) == 0x4489)
				break;
		}
		if (mbuf >= mend || *mbuf == 0)
			break;

		rotateonebit (bigmfmbuf, mend, check_offset);
		check_offset = 0;

		while (getmfmword (mbuf) == 0x4489)
			mbuf+= 1 * 2;
		mbuf2 =	mbuf + 8;

		odd = getmfmlong (mbuf);
		even = getmfmlong (mbuf + 2 * 2);
		mbuf +=	4 * 2;
		id = (odd << 1) | even;

		trackoffs = (id & 0xff00) >> 8;
		if (trackoffs + 1 > drvsec) {
			outlog("illegal sector offset %d\n",trackoffs);
			ok = 0;
			mbuf = mbuf2;
			continue;
		}
		if ((id >> 24) != 0xff) {
			outlog ("sector %d format type %02.2X?\n", trackoffs, id >> 24);
			ok = 0;
		}
		chksum = odd ^ even;
		slabel = 0;
		for (i = 0; i < 4; i++) {
			odd = getmfmlong (mbuf);
			even = getmfmlong (mbuf + 8 * 2);
			mbuf += 2* 2;

			dlong = (odd << 1) | even;
			if (dlong) slabel = 1;
			chksum ^= odd ^ even;
		}
		mbuf += 8 * 2;
		odd = getmfmlong (mbuf);
		even = getmfmlong (mbuf + 2 * 2);
		mbuf += 4 * 2;
		if (((odd << 1) | even) != chksum) {
			outlog("sector %d header crc error\n", trackoffs);
			ok = 0;
			mbuf = mbuf2;
			continue;
		}
		outlog("sector %d header crc ok\n", trackoffs);
		if (((id & 0x00ff0000) >> 16) != (uae_u32)fdi->current_track) {
			outlog("illegal track number %d <> %d\n",fdi->current_track,(id & 0x00ff0000) >> 16);
			ok++;
			mbuf = mbuf2;
			continue;
		}
		odd = getmfmlong (mbuf);
		even = getmfmlong (mbuf + 2 * 2);
		mbuf += 4 * 2;
		chksum = (odd << 1) | even;
		secdata = secbuf + 32;
		for (i = 0; i < 128; i++) {
			odd = getmfmlong (mbuf);
			even = getmfmlong (mbuf + 256 * 2);
			mbuf += 2 * 2;
			dlong = (odd << 1) | even;
			*secdata++ = (uae_u8) (dlong >> 24);
			*secdata++ = (uae_u8) (dlong >> 16);
			*secdata++ = (uae_u8) (dlong >> 8);
			*secdata++ = (uae_u8) dlong;
			chksum ^= odd ^ even;
		}
		mbuf += 256 * 2;
		if (chksum) {
			outlog("sector %d data checksum error\n",trackoffs);
			ok = 0;
		} else if (sectable[trackoffs]) {
			outlog("sector %d already found?\n", trackoffs);
			mbuf = mbuf2;
		} else {
			outlog("sector %d ok\n",trackoffs);
			if (slabel) outlog("(non-empty sector header)\n");
			sectable[trackoffs] = 1;
			secwritten++;
			if (trackoffs == 9)
				mbuf += 0x228;
		}
	}
	for (i = 0; i < drvsec; i++) {
		if (!sectable[i]) {
			outlog ("sector %d missing\n", i);
			ok = 0;
		}
	}
	return ok;
}
#endif

static void amiga_data_raw(FDI *fdi, uae_u8 *secbuf, uae_u8 *crc, int len) {
        int i;
        uae_u8 crcbuf[4];

        if (!crc) {
                memset(crcbuf, 0, 4);
        } else {
                memcpy(crcbuf, crc, 4);
        }
        for (i = 0; i < 4; i++)
                byte_mfm_add(fdi, crcbuf[i]);
        for (i = 0; i < len; i++)
                byte_mfm_add(fdi, secbuf[i]);
}

static void amiga_data(FDI *fdi, uae_u8 *secbuf) {
        uae_u16 mfmbuf[4 + 512];
        uae_u32 dodd, deven, dck;
        int i;

        for (i = 0; i < 512; i += 4) {
                deven = ((secbuf[i + 0] << 24) | (secbuf[i + 1] << 16) | (secbuf[i + 2] << 8) | (secbuf[i + 3]));
                dodd = deven >> 1;
                deven &= 0x55555555;
                dodd &= 0x55555555;
                mfmbuf[(i >> 1) + 4] = (uae_u16)(dodd >> 16);
                mfmbuf[(i >> 1) + 5] = (uae_u16)dodd;
                mfmbuf[(i >> 1) + 256 + 4] = (uae_u16)(deven >> 16);
                mfmbuf[(i >> 1) + 256 + 5] = (uae_u16)deven;
        }
        dck = 0;
        for (i = 4; i < 4 + 512; i += 2)
                dck ^= (mfmbuf[i] << 16) | mfmbuf[i + 1];
        deven = dodd = dck;
        dodd >>= 1;
        deven &= 0x55555555;
        dodd &= 0x55555555;
        mfmbuf[0] = (uae_u16)(dodd >> 16);
        mfmbuf[1] = (uae_u16)dodd;
        mfmbuf[2] = (uae_u16)(deven >> 16);
        mfmbuf[3] = (uae_u16)deven;

        for (i = 0; i < 4 + 512; i++)
                word_post_mfm_add(fdi, mfmbuf[i]);
}

static void amiga_sector_header(FDI *fdi, uae_u8 *header, uae_u8 *data, int sector, int untilgap) {
        uae_u8 headerbuf[4], databuf[16];
        uae_u32 deven, dodd, hck;
        uae_u16 mfmbuf[24];
        int i;

        byte_mfm_add(fdi, 0);
        byte_mfm_add(fdi, 0);
        word_add(fdi, 0x4489);
        word_add(fdi, 0x4489);
        if (header) {
                memcpy(headerbuf, header, 4);
        } else {
                headerbuf[0] = 0xff;
                headerbuf[1] = (uae_u8)fdi->current_track;
                headerbuf[2] = (uae_u8)sector;
                headerbuf[3] = (uae_u8)untilgap;
        }
        if (data)
                memcpy(databuf, data, 16);
        else
                memset(databuf, 0, 16);

        deven = ((headerbuf[0] << 24) | (headerbuf[1] << 16) | (headerbuf[2] << 8) | (headerbuf[3]));
        dodd = deven >> 1;
        deven &= 0x55555555;
        dodd &= 0x55555555;
        mfmbuf[0] = (uae_u16)(dodd >> 16);
        mfmbuf[1] = (uae_u16)dodd;
        mfmbuf[2] = (uae_u16)(deven >> 16);
        mfmbuf[3] = (uae_u16)deven;
        for (i = 0; i < 16; i += 4) {
                deven = ((databuf[i] << 24) | (databuf[i + 1] << 16) | (databuf[i + 2] << 8) | (databuf[i + 3]));
                dodd = deven >> 1;
                deven &= 0x55555555;
                dodd &= 0x55555555;
                mfmbuf[(i >> 1) + 0 + 4] = (uae_u16)(dodd >> 16);
                mfmbuf[(i >> 1) + 0 + 5] = (uae_u16)dodd;
                mfmbuf[(i >> 1) + 8 + 4] = (uae_u16)(deven >> 16);
                mfmbuf[(i >> 1) + 8 + 5] = (uae_u16)deven;
        }
        hck = 0;
        for (i = 0; i < 4 + 16; i += 2)
                hck ^= (mfmbuf[i] << 16) | mfmbuf[i + 1];
        deven = dodd = hck;
        dodd >>= 1;
        deven &= 0x55555555;
        dodd &= 0x55555555;
        mfmbuf[20] = (uae_u16)(dodd >> 16);
        mfmbuf[21] = (uae_u16)dodd;
        mfmbuf[22] = (uae_u16)(deven >> 16);
        mfmbuf[23] = (uae_u16)deven;

        for (i = 0; i < 4 + 16 + 4; i++)
                word_post_mfm_add(fdi, mfmbuf[i]);
}

/* standard super-extended Amiga sector header */
static void s20(FDI *fdi) {
        bit_drop_next(fdi);
        debuglog("s20:header=%s,data=%s", datalog(fdi->track_src, 4), datalog(fdi->track_src + 4, 16));
        amiga_sector_header(fdi, fdi->track_src, fdi->track_src + 4, 0, 0);
        fdi->track_src += 4 + 16;
}
/* standard extended Amiga sector header */
static void s21(FDI *fdi) {
        bit_drop_next(fdi);
        debuglog("s21:header=%s", datalog(fdi->track_src, 4));
        amiga_sector_header(fdi, fdi->track_src, 0, 0, 0);
        fdi->track_src += 4;
}
/* standard Amiga sector header */
static void s22(FDI *fdi) {
        bit_drop_next(fdi);
        debuglog("s22:sector=%d,untilgap=%d", fdi->track_src[0], fdi->track_src[1]);
        amiga_sector_header(fdi, 0, 0, fdi->track_src[0], fdi->track_src[1]);
        fdi->track_src += 2;
}
/* standard 512-byte, CRC-correct Amiga data */
static void s23(FDI *fdi) {
        debuglog("s23:data=%s", datalog(fdi->track_src, 512));
        amiga_data(fdi, fdi->track_src);
        fdi->track_src += 512;
}
/* not-decoded, 128*2^x-byte, CRC-correct Amiga data */
static void s24(FDI *fdi) {
        int shift = *fdi->track_src++;
        debuglog("s24:shift=%d,data=%s", shift, datalog(fdi->track_src, 128 << shift));
        amiga_data_raw(fdi, fdi->track_src, 0, 128 << shift);
        fdi->track_src += 128 << shift;
}
/* not-decoded, 128*2^x-byte, CRC-incorrect Amiga data */
static void s25(FDI *fdi) {
        int shift = *fdi->track_src++;
        debuglog("s25:shift=%d,crc=%s,data=%s", shift, datalog(fdi->track_src, 4), datalog(fdi->track_src + 4, 128 << shift));
        amiga_data_raw(fdi, fdi->track_src + 4, fdi->track_src, 128 << shift);
        fdi->track_src += 4 + (128 << shift);
}
/* standard extended Amiga sector */
static void s26(FDI *fdi) {
        s21(fdi);
        debuglog("s26:data=%s", datalog(fdi->track_src, 512));
        amiga_data(fdi, fdi->track_src);
        fdi->track_src += 512;
}
/* standard short Amiga sector */
static void s27(FDI *fdi) {
        s22(fdi);
        debuglog("s27:data=%s", datalog(fdi->track_src, 512));
        amiga_data(fdi, fdi->track_src);
        fdi->track_src += 512;
}

/* *** */
/* IBM */
/* *** */

static uae_u16 ibm_crc(uae_u8 byte, int reset) {
        static uae_u16 crc;
        int i;

        if (reset)
                crc = 0xcdb4;
        for (i = 0; i < 8; i++) {
                if (crc & 0x8000) {
                        crc <<= 1;
                        if (!(byte & 0x80))
                                crc ^= 0x1021;
                } else {
                        crc <<= 1;
                        if (byte & 0x80)
                                crc ^= 0x1021;
                }
                byte <<= 1;
        }
        return crc;
}

static void ibm_data(FDI *fdi, uae_u8 *data, uae_u8 *crc, int len) {
        int i;
        uae_u8 crcbuf[2];
        uae_u16 crcv = 0;

        word_add(fdi, 0x4489);
        word_add(fdi, 0x4489);
        word_add(fdi, 0x4489);
        byte_mfm_add(fdi, 0xfb);
        ibm_crc(0xfb, 1);
        for (i = 0; i < len; i++) {
                byte_mfm_add(fdi, data[i]);
                crcv = ibm_crc(data[i], 0);
        }
        if (!crc) {
                crc = crcbuf;
                crc[0] = (uae_u8)(crcv >> 8);
                crc[1] = (uae_u8)crcv;
        }
        byte_mfm_add(fdi, crc[0]);
        byte_mfm_add(fdi, crc[1]);
}

static void ibm_sector_header(FDI *fdi, uae_u8 *data, uae_u8 *crc, int secnum, int pre) {
        uae_u8 secbuf[5];
        uae_u8 crcbuf[2];
        uae_u16 crcv;
        int i;

        if (pre)
                bytes_mfm_add(fdi, 0, 12);
        word_add(fdi, 0x4489);
        word_add(fdi, 0x4489);
        word_add(fdi, 0x4489);
        secbuf[0] = 0xfe;
        if (secnum >= 0) {
                secbuf[1] = (uae_u8)(fdi->current_track / 2);
                secbuf[2] = (uae_u8)(fdi->current_track % 2);
                secbuf[3] = (uae_u8)secnum;
                secbuf[4] = 2;
        } else {
                memcpy(secbuf + 1, data, 4);
        }
        ibm_crc(secbuf[0], 1);
        ibm_crc(secbuf[1], 0);
        ibm_crc(secbuf[2], 0);
        ibm_crc(secbuf[3], 0);
        crcv = ibm_crc(secbuf[4], 0);
        if (crc) {
                memcpy(crcbuf, crc, 2);
        } else {
                crcbuf[0] = (uae_u8)(crcv >> 8);
                crcbuf[1] = (uae_u8)crcv;
        }
        /* data */
        for (i = 0; i < 5; i++)
                byte_mfm_add(fdi, secbuf[i]);
        /* crc */
        byte_mfm_add(fdi, crcbuf[0]);
        byte_mfm_add(fdi, crcbuf[1]);
}

/* standard IBM index address mark */
static void s10(FDI *fdi) {
        bit_drop_next(fdi);
        bytes_mfm_add(fdi, 0, 12);
        word_add(fdi, 0x5224);
        word_add(fdi, 0x5224);
        word_add(fdi, 0x5224);
        byte_mfm_add(fdi, 0xfc);
}
/* standard IBM pre-gap */
static void s11(FDI *fdi) {
        bit_drop_next(fdi);
        bytes_mfm_add(fdi, 0x4e, 78);
        bit_dedrop(fdi);
        s10(fdi);
        bytes_mfm_add(fdi, 0x4e, 50);
}
/* standard ST pre-gap */
static void s12(FDI *fdi) {
        bit_drop_next(fdi);
        bytes_mfm_add(fdi, 0x4e, 78);
}
/* standard extended IBM sector header */
static void s13(FDI *fdi) {
        bit_drop_next(fdi);
        debuglog("s13:header=%s", datalog(fdi->track_src, 4));
        ibm_sector_header(fdi, fdi->track_src, 0, -1, 1);
        fdi->track_src += 4;
}
/* standard mini-extended IBM sector header */
static void s14(FDI *fdi) {
        debuglog("s14:header=%s", datalog(fdi->track_src, 4));
        ibm_sector_header(fdi, fdi->track_src, 0, -1, 0);
        fdi->track_src += 4;
}
/* standard short IBM sector header */
static void s15(FDI *fdi) {
        bit_drop_next(fdi);
        debuglog("s15:sector=%d", *fdi->track_src);
        ibm_sector_header(fdi, 0, 0, *fdi->track_src++, 1);
}
/* standard mini-short IBM sector header */
static void s16(FDI *fdi) {
        debuglog("s16:track=%d", *fdi->track_src);
        ibm_sector_header(fdi, 0, 0, *fdi->track_src++, 0);
}
/* standard CRC-incorrect mini-extended IBM sector header */
static void s17(FDI *fdi) {
        debuglog("s17:header=%s,crc=%s", datalog(fdi->track_src, 4), datalog(fdi->track_src + 4, 2));
        ibm_sector_header(fdi, fdi->track_src, fdi->track_src + 4, -1, 0);
        fdi->track_src += 4 + 2;
}
/* standard CRC-incorrect mini-short IBM sector header */
static void s18(FDI *fdi) {
        debuglog("s18:sector=%d,header=%s", *fdi->track_src, datalog(fdi->track_src + 1, 4));
        ibm_sector_header(fdi, 0, fdi->track_src + 1, *fdi->track_src, 0);
        fdi->track_src += 1 + 4;
}
/* standard 512-byte CRC-correct IBM data */
static void s19(FDI *fdi) {
        debuglog("s19:data=%s", datalog(fdi->track_src, 512));
        ibm_data(fdi, fdi->track_src, 0, 512);
        fdi->track_src += 512;
}
/* standard 128*2^x-byte-byte CRC-correct IBM data */
static void s1a(FDI *fdi) {
        int shift = *fdi->track_src++;
        debuglog("s1a:shift=%d,data=%s", shift, datalog(fdi->track_src, 128 << shift));
        ibm_data(fdi, fdi->track_src, 0, 128 << shift);
        fdi->track_src += 128 << shift;
}
/* standard 128*2^x-byte-byte CRC-incorrect IBM data */
static void s1b(FDI *fdi) {
        int shift = *fdi->track_src++;
        debuglog("s1b:shift=%d,crc=%s,data=%s", shift, datalog(fdi->track_src + (128 << shift), 2),
                 datalog(fdi->track_src, 128 << shift));
        ibm_data(fdi, fdi->track_src, fdi->track_src + (128 << shift), 128 << shift);
        fdi->track_src += (128 << shift) + 2;
}
/* standard extended IBM sector */
static void s1c(FDI *fdi) {
        int shift = fdi->track_src[3];
        s13(fdi);
        bytes_mfm_add(fdi, 0x4e, 22);
        bytes_mfm_add(fdi, 0x00, 12);
        ibm_data(fdi, fdi->track_src, 0, 128 << shift);
        fdi->track_src += 128 << shift;
}
/* standard short IBM sector */
static void s1d(FDI *fdi) {
        s15(fdi);
        bytes_mfm_add(fdi, 0x4e, 22);
        bytes_mfm_add(fdi, 0x00, 12);
        s19(fdi);
}

/* end marker */
static void sff(FDI *fdi) {}

typedef void (*decode_described_track_func)(FDI *);

static decode_described_track_func decode_sectors_described_track[] = {
        s00, s01, s02, s03, s04, dxx, dxx, dxx, s08, s09, s0a, s0b, s0c, s0d, dxx, dxx, /* 00-0F */
        s10, s11, s12, s13, s14, s15, s16, s17, s18, s19, s1a, s1b, s1c, s1d, dxx, dxx, /* 10-1F */
        s20, s21, s22, s23, s24, s25, s26, s27, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, /* 20-2F */
        dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, /* 30-3F */
        dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, /* 40-4F */
        dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, /* 50-5F */
        dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, /* 60-6F */
        dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, /* 70-7F */
        dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, /* 80-8F */
        dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, /* 90-9F */
        dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, /* A0-AF */
        dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, /* B0-BF */
        dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, /* C0-CF */
        dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, /* D0-DF */
        dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, /* E0-EF */
        dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, dxx, sff  /* F0-FF */
};

static void track_amiga(struct fdi *fdi, int first_sector, int max_sector) {
        int i;

        bit_add(fdi, 0);
        bit_drop_next(fdi);
        for (i = 0; i < max_sector; i++) {
                amiga_sector_header(fdi, 0, 0, first_sector, max_sector - i);
                amiga_data(fdi, fdi->track_src + first_sector * 512);
                first_sector++;
                if (first_sector >= max_sector)
                        first_sector = 0;
        }
        bytes_mfm_add(fdi, 0, 260); /* gap */
}
static void track_atari_st(struct fdi *fdi, int max_sector) {
        int i, gap3 = 0;
        uae_u8 *p = fdi->track_src;

        switch (max_sector) {
        case 9:
                gap3 = 40;
                break;
        case 10:
                gap3 = 24;
                break;
        }
        s15(fdi);
        for (i = 0; i < max_sector; i++) {
                byte_mfm_add(fdi, 0x4e);
                byte_mfm_add(fdi, 0x4e);
                ibm_sector_header(fdi, 0, 0, fdi->current_track, 1);
                ibm_data(fdi, p + i * 512, 0, 512);
                bytes_mfm_add(fdi, 0x4e, gap3);
        }
        bytes_mfm_add(fdi, 0x4e, 660 - gap3);
        fdi->track_src += fdi->track_len * 256;
}
static void track_pc(struct fdi *fdi, int max_sector) {
        int i, gap3;
        uae_u8 *p = fdi->track_src;

        switch (max_sector) {
        case 8:
                gap3 = 116;
                break;
        case 9:
                gap3 = 54;
                break;
        default:
                gap3 = 100; /* fixme */
                break;
        }
        s11(fdi);
        for (i = 0; i < max_sector; i++) {
                byte_mfm_add(fdi, 0x4e);
                byte_mfm_add(fdi, 0x4e);
                ibm_sector_header(fdi, 0, 0, fdi->current_track, 1);
                ibm_data(fdi, p + i * 512, 0, 512);
                bytes_mfm_add(fdi, 0x4e, gap3);
        }
        bytes_mfm_add(fdi, 0x4e, 600 - gap3);
        fdi->track_src += fdi->track_len * 256;
}

/* amiga dd */
static void track_amiga_dd(struct fdi *fdi) {
        uae_u8 *p = fdi->track_src;
        track_amiga(fdi, fdi->track_len >> 4, 11);
        fdi->track_src = p + (fdi->track_len & 15) * 512;
}
/* amiga hd */
static void track_amiga_hd(struct fdi *fdi) {
        uae_u8 *p = fdi->track_src;
        track_amiga(fdi, 0, 22);
        fdi->track_src = p + fdi->track_len * 256;
}
/* atari st 9 sector */
static void track_atari_st_9(struct fdi *fdi) { track_atari_st(fdi, 9); }
/* atari st 10 sector */
static void track_atari_st_10(struct fdi *fdi) { track_atari_st(fdi, 10); }
/* pc 8 sector */
static void track_pc_8(struct fdi *fdi) { track_pc(fdi, 8); }
/* pc 9 sector */
static void track_pc_9(struct fdi *fdi) { track_pc(fdi, 9); }
/* pc 15 sector */
static void track_pc_15(struct fdi *fdi) { track_pc(fdi, 15); }
/* pc 18 sector */
static void track_pc_18(struct fdi *fdi) { track_pc(fdi, 18); }
/* pc 36 sector */
static void track_pc_36(struct fdi *fdi) { track_pc(fdi, 36); }

typedef void (*decode_normal_track_func)(FDI *);

static decode_normal_track_func decode_normal_track[] = {
        track_empty, /* 0 */
        track_amiga_dd,
        track_amiga_hd, /* 1-2 */
        track_atari_st_9,
        track_atari_st_10, /* 3-4 */
        track_pc_8,
        track_pc_9,
        track_pc_15,
        track_pc_18,
        track_pc_36, /* 5-9 */
        zxx,
        zxx,
        zxx,
        zxx,
        zxx /* A-F */
};

static void fix_mfm_sync(FDI *fdi) {
        int i, pos, off1, off2, off3, mask1, mask2, mask3;

        for (i = 0; i < fdi->mfmsync_offset; i++) {
                pos = fdi->mfmsync_buffer[i];
                off1 = (pos - 1) >> 3;
                off2 = (pos + 1) >> 3;
                off3 = pos >> 3;
                mask1 = 1 << (7 - ((pos - 1) & 7));
                mask2 = 1 << (7 - ((pos + 1) & 7));
                mask3 = 1 << (7 - (pos & 7));
                if (!(fdi->track_dst[off1] & mask1) && !(fdi->track_dst[off2] & mask2))
                        fdi->track_dst[off3] |= mask3;
                else
                        fdi->track_dst[off3] &= ~mask3;
        }
}

static int handle_sectors_described_track(FDI *fdi) {
        int oldout;
        uae_u8 *start_src = fdi->track_src;
        fdi->encoding_type = *fdi->track_src++;
        fdi->index_offset = get_u32(fdi->track_src);
        fdi->index_offset >>= 8;
        fdi->track_src += 3;
        outlog("sectors_described, index offset: %d\n", fdi->index_offset);

        do {
                fdi->track_type = *fdi->track_src++;
                outlog("%06.6X %06.6X %02.2X:", fdi->track_src - start_src + 0x200, fdi->out / 8, fdi->track_type);
                oldout = fdi->out;
                decode_sectors_described_track[fdi->track_type](fdi);
                outlog(" %d\n", fdi->out - oldout);
                oldout = fdi->out;
                if (fdi->out < 0 || fdi->err) {
                        outlog("\nin %d bytes, out %d bits\n", fdi->track_src - fdi->track_src_buffer, fdi->out);
                        return -1;
                }
                if (fdi->track_src - fdi->track_src_buffer >= fdi->track_src_len) {
                        outlog("source buffer overrun, previous type: %02.2X\n", fdi->track_type);
                        return -1;
                }
        } while (fdi->track_type != 0xff);
        outlog("\n");
        fix_mfm_sync(fdi);
        return fdi->out;
}

static uae_u8 *fdi_decompress(int pulses, uae_u8 *sizep, uae_u8 *src, int *dofree) {
        uae_u32 size = get_u24(sizep);
        uae_u32 *dst2;
        int len = size & 0x3fffff;
        uae_u8 *dst;
        int mode = size >> 22, i;

        *dofree = 0;
        if (mode == 0 && pulses * 2 > len)
                mode = 1;
        if (mode == 0) {
                dst2 = (uae_u32 *)src;
                dst = src;
                for (i = 0; i < pulses; i++) {
                        *dst2++ = get_u32(src);
                        src += 4;
                }
        } else if (mode == 1) {
                dst = fdi_malloc(pulses * 4);
                *dofree = 1;
                fdi_decode(src, pulses, dst);
        } else {
                dst = 0;
        }
        return dst;
}

static void dumpstream(int track, uae_u8 *stream, int len) {
#if 0
	char name[100];
	FILE *f;

	sprintf (name, "track_%d.raw", track);
	f = fopen(name, "wb");
	fwrite (stream, 1, len * 4, f);
	fclose (f);
#endif
}

static int bitoffset;

STATIC_INLINE void addbit(uae_u8 *p, int bit) {
        int off1 = bitoffset / 8;
        int off2 = bitoffset % 8;
        p[off1] |= bit << (7 - off2);
        bitoffset++;
}

struct pulse_sample {
        uint32_t size;
        int number_of_bits;
};

#define FDI_MAX_ARRAY 10        /* change this value as you want */
static int pulse_limitval = 15; /* tolerance of 15% */
static struct pulse_sample psarray[FDI_MAX_ARRAY];
static int array_index;
static unsigned long total;
static int totaldiv;

static void init_array(uint32_t standard_MFM_2_bit_cell_size, int nb_of_bits) {
        int i;

        for (i = 0; i < FDI_MAX_ARRAY; i++) {
                psarray[i].size = standard_MFM_2_bit_cell_size; // That is (total track length / 50000) for Amiga double density
                total += psarray[i].size;
                psarray[i].number_of_bits = nb_of_bits;
                totaldiv += psarray[i].number_of_bits;
        }
        array_index = 0;
}

#if 0

static void fdi2_decode (FDI *fdi, uint32_t totalavg, uae_u32 *avgp, uae_u32 *minp, uae_u32 *maxp, uae_u8 *idx, int maxidx, int *indexoffsetp, int pulses, int mfm)
{
	uint32_t adjust;
	uint32_t adjusted_pulse;
	uint32_t standard_MFM_2_bit_cell_size = totalavg / 50000;
	uint32_t standard_MFM_8_bit_cell_size = totalavg / 12500;
	int real_size, i, j, eodat, outstep;
	int indexoffset = *indexoffsetp;
	uae_u8 *d = fdi->track_dst_buffer;
	uae_u16 *pt = fdi->track_dst_buffer_timing;
	uae_u32 ref_pulse, pulse;

	/* detects a long-enough stable pulse coming just after another stable pulse */
	i = 1;
	while ( (i < pulses) && ( (idx[i] < maxidx)
		|| (idx[i - 1] < maxidx)
		|| (avgp[i] < (standard_MFM_2_bit_cell_size - (standard_MFM_2_bit_cell_size / 4))) ) )
			i++;
	if (i == pulses)  {
		outlog ("No stable and long-enough pulse in track.\n");
		return;
	}
	i--;
	eodat = i;
	adjust = 0;
	total = 0;
	totaldiv = 0;
	init_array(standard_MFM_2_bit_cell_size, 2);
	bitoffset = 0;
	ref_pulse = 0;
	outstep = 0;
	while (outstep < 2) {

		/* calculates the current average bitrate from previous decoded data */
		uae_u32 avg_size = (total << 3) / totaldiv; /* this is the new average size for one MFM bit */
		/* uae_u32 avg_size = (uae_u32)((((float)total)*8.0) / ((float)totaldiv)); */
		/* you can try tighter ranges than 25%, or wider ranges. I would probably go for tighter... */
		if ((avg_size < (standard_MFM_8_bit_cell_size - (pulse_limitval * standard_MFM_8_bit_cell_size / 100))) ||
			(avg_size > (standard_MFM_8_bit_cell_size + (pulse_limitval * standard_MFM_8_bit_cell_size / 100)))) {
				//init_array(standard_MFM_2_bit_cell_size, 2);
				avg_size = standard_MFM_8_bit_cell_size;
		}
		/* this is to prevent the average value from going too far
		* from the theoretical value, otherwise it could progressively go to (2 *
		* real value), or (real value / 2), etc. */

		/* gets the next long-enough pulse (this may require more than one pulse) */
		pulse = 0;
		while (pulse < ((avg_size / 4) - (avg_size / 16))) {
			int indx;
			i++;
			if (i >= pulses)
				i = 0;
			indx = idx[i];
			if (rand() <= (indx * RAND_MAX) / maxidx) {
				pulse += avgp[i] - ref_pulse;
				if (indx >= maxidx)
					ref_pulse = 0;
				else
					ref_pulse = avgp[i];
			}
			if (i == eodat)
				outstep++;
			if (outstep == 1 && indexoffset == i)
			    *indexoffsetp = bitoffset;
		}

		/* gets the size in bits from the pulse width, considering the current average bitrate */
		adjusted_pulse = pulse;
		real_size = 0;
		while (adjusted_pulse >= avg_size) {
			real_size += 4;
			adjusted_pulse -= avg_size / 2;
		}
		adjusted_pulse <<= 3;
		while (adjusted_pulse >= ((avg_size * 4) + (avg_size / 4))) {
			real_size += 2;
			adjusted_pulse -= avg_size * 2;
		}
		if (adjusted_pulse >= ((avg_size * 3) + (avg_size / 4))) {
			if (adjusted_pulse <= ((avg_size * 4) - (avg_size / 4))) {
				if ((2 * ((adjusted_pulse >> 2) - adjust)) <= ((2 * avg_size) - (avg_size / 4)))
					real_size += 3;
				else
					real_size += 4;
			} else
				real_size += 4;
		} else {
			if (adjusted_pulse > ((avg_size * 3) - (avg_size / 4))) {
				real_size += 3;
			} else {
				if (adjusted_pulse >= ((avg_size * 2) + (avg_size / 4))) {
					if ((2 * ((adjusted_pulse >> 2) - adjust)) < (avg_size + (avg_size / 4)))
						real_size += 2;
					else
						real_size += 3;
				} else
					real_size += 2;
			}
		}

		if (outstep == 1) {
			for (j = real_size; j > 1; j--)
				addbit (d, 0);
			addbit (d, 1);
			for (j = 0; j <	real_size; j++)
				*pt++ =	(uae_u16)(pulse / real_size);
		}

		/* prepares for the next pulse */
		adjust = ((real_size * avg_size)/8) - pulse;
		total -= psarray[array_index].size;
		totaldiv -= psarray[array_index].number_of_bits;
		psarray[array_index].size = pulse;
		psarray[array_index].number_of_bits = real_size;
		total += pulse;
		totaldiv += real_size;
		array_index++;
		if (array_index	>= FDI_MAX_ARRAY)
			array_index = 0;
	}

	fdi->out = bitoffset;
}

#else

static void fdi2_decode(FDI *fdi, uint32_t totalavg, uae_u32 *avgp, uae_u32 *minp, uae_u32 *maxp, uae_u8 *idx, int maxidx,
                        int *indexoffsetp, int pulses, int mfm) {
        uint32_t adjust;
        uint32_t adjusted_pulse;
        uint32_t standard_MFM_2_bit_cell_size = totalavg / 50000;
        uint32_t standard_MFM_8_bit_cell_size = totalavg / 12500;
        int real_size, i, j, nexti, eodat, outstep, randval;
        int indexoffset = *indexoffsetp;
        uae_u8 *d = fdi->track_dst_buffer;
        uae_u16 *pt = fdi->track_dst_buffer_timing;
        uae_u32 ref_pulse, pulse;
        long jitter;

        /* detects a long-enough stable pulse coming just after another stable pulse */
        i = 1;
        while ((i < pulses) && ((idx[i] < maxidx) || (idx[i - 1] < maxidx) ||
                                (minp[i] < (standard_MFM_2_bit_cell_size - (standard_MFM_2_bit_cell_size / 4)))))
                i++;
        if (i == pulses) {
                outlog("FDI: No stable and long-enough pulse in track.\n");
                return;
        }
        nexti = i;
        eodat = i;
        i--;
        adjust = 0;
        total = 0;
        totaldiv = 0;
        init_array(standard_MFM_2_bit_cell_size, 1 + mfm);
        bitoffset = 0;
        ref_pulse = 0;
        jitter = 0;
        outstep = -1;
        while (outstep < 2) {

                /* calculates the current average bitrate from previous decoded data */
                uae_u32 avg_size = (total << (2 + mfm)) / totaldiv; /* this is the new average size for one MFM bit */
                /* uae_u32 avg_size = (uae_u32)((((float)total)*((float)(mfm+1))*4.0) / ((float)totaldiv)); */
                /* you can try tighter ranges than 25%, or wider ranges. I would probably go for tighter... */
                if ((avg_size < (standard_MFM_8_bit_cell_size - (pulse_limitval * standard_MFM_8_bit_cell_size / 100))) ||
                    (avg_size > (standard_MFM_8_bit_cell_size + (pulse_limitval * standard_MFM_8_bit_cell_size / 100)))) {
                        // init_array(standard_MFM_2_bit_cell_size, mfm + 1);
                        avg_size = standard_MFM_8_bit_cell_size;
                }
                /* this	is to prevent the average value from going too far
                 * from the theoretical value, otherwise it could progressively go to (2 *
                 * real value), or (real value / 2), etc. */

                /* gets the next long-enough pulse (this may require more than one pulse) */
                pulse = 0;
                while (pulse < ((avg_size / 4) - (avg_size / 16))) {
                        uae_u32 avg_pulse, min_pulse, max_pulse;
                        i++;
                        if (i >= pulses)
                                i = 0;
                        if (i == nexti) {
                                do {
                                        nexti++;
                                        if (nexti >= pulses)
                                                nexti = 0;
                                } while (idx[nexti] < maxidx);
                        }
                        if (idx[i] >= maxidx) { /* stable pulse */
                                avg_pulse = avgp[i] - jitter;
                                min_pulse = minp[i];
                                max_pulse = maxp[i];
                                if (jitter >= 0)
                                        max_pulse -= jitter;
                                else
                                        min_pulse -= jitter;
                                if ((maxp[nexti] - avgp[nexti]) < (avg_pulse - min_pulse))
                                        min_pulse = avg_pulse - (maxp[nexti] - avgp[nexti]);
                                if ((avgp[nexti] - minp[nexti]) < (max_pulse - avg_pulse))
                                        max_pulse = avg_pulse + (avgp[nexti] - minp[nexti]);
                                if (min_pulse < ref_pulse)
                                        min_pulse = ref_pulse;
                                randval = rand();
                                if (randval < (RAND_MAX / 2)) {
                                        if (randval > (RAND_MAX / 4)) {
                                                if (randval <= (3 * (int64_t)RAND_MAX / 8))
                                                        randval = (2 * randval) - (RAND_MAX / 4);
                                                else
                                                        randval = (4 * randval) - RAND_MAX;
                                        }
                                        jitter = 0 - (randval * (avg_pulse - min_pulse)) / RAND_MAX;
                                } else {
                                        randval -= RAND_MAX / 2;
                                        if (randval > (RAND_MAX / 4)) {
                                                if (randval <= (3 * (int64_t)RAND_MAX / 8))
                                                        randval = (2 * randval) - (RAND_MAX / 4);
                                                else
                                                        randval = (4 * randval) - RAND_MAX;
                                        }
                                        jitter = (randval * (max_pulse - avg_pulse)) / RAND_MAX;
                                }
                                avg_pulse += jitter;
                                if ((avg_pulse < min_pulse) || (avg_pulse > max_pulse)) {
                                        outlog("FDI: avg_pulse outside bounds! avg=%u min=%u max=%u\n", avg_pulse, min_pulse,
                                               max_pulse);
                                        outlog("FDI: avgp=%u (%u) minp=%u (%u) maxp=%u (%u) jitter=%d i=%d ni=%d\n", avgp[i],
                                               avgp[nexti], minp[i], minp[nexti], maxp[i], maxp[nexti], jitter, i, nexti);
                                }
                                if (avg_pulse < ref_pulse)
                                        outlog("FDI: avg_pulse < ref_pulse! (%u < %u)\n", avg_pulse, ref_pulse);
                                pulse += avg_pulse - ref_pulse;
                                ref_pulse = 0;
                                if (i == eodat)
                                        outstep++;
                        } else if (rand() <= ((idx[i] * RAND_MAX) / maxidx)) {
                                avg_pulse = avgp[i];
                                min_pulse = minp[i];
                                max_pulse = maxp[i];
                                randval = rand();
                                if (randval < (RAND_MAX / 2)) {
                                        if (randval > (RAND_MAX / 4)) {
                                                if (randval <= (3 * (int64_t)RAND_MAX / 8))
                                                        randval = (2 * randval) - (RAND_MAX / 4);
                                                else
                                                        randval = (4 * randval) - RAND_MAX;
                                        }
                                        avg_pulse -= (randval * (avg_pulse - min_pulse)) / RAND_MAX;
                                } else {
                                        randval -= RAND_MAX / 2;
                                        if (randval > (RAND_MAX / 4)) {
                                                if (randval <= (3 * (int64_t)RAND_MAX / 8))
                                                        randval = (2 * randval) - (RAND_MAX / 4);
                                                else
                                                        randval = (4 * randval) - RAND_MAX;
                                        }
                                        avg_pulse += (randval * (max_pulse - avg_pulse)) / RAND_MAX;
                                }
                                if ((avg_pulse > ref_pulse) && (avg_pulse < (avgp[nexti] - jitter))) {
                                        pulse += avg_pulse - ref_pulse;
                                        ref_pulse = avg_pulse;
                                }
                        }
                        if (outstep == 1 && indexoffset == i)
                                *indexoffsetp = bitoffset;
                }

                /* gets the size in bits from the pulse width, considering the current average bitrate */
                adjusted_pulse = pulse;
                real_size = 0;
                if (mfm) {
                        while (adjusted_pulse >= avg_size) {
                                real_size += 4;
                                adjusted_pulse -= avg_size / 2;
                        }
                        adjusted_pulse <<= 3;
                        while (adjusted_pulse >= ((avg_size * 4) + (avg_size / 4))) {
                                real_size += 2;
                                adjusted_pulse -= avg_size * 2;
                        }
                        if (adjusted_pulse >= ((avg_size * 3) + (avg_size / 4))) {
                                if (adjusted_pulse <= ((avg_size * 4) - (avg_size / 4))) {
                                        if ((2 * ((adjusted_pulse >> 2) - adjust)) <= ((2 * avg_size) - (avg_size / 4)))
                                                real_size += 3;
                                        else
                                                real_size += 4;
                                } else
                                        real_size += 4;
                        } else {
                                if (adjusted_pulse > ((avg_size * 3) - (avg_size / 4))) {
                                        real_size += 3;
                                } else {
                                        if (adjusted_pulse >= ((avg_size * 2) + (avg_size / 4))) {
                                                if ((2 * ((adjusted_pulse >> 2) - adjust)) < (avg_size + (avg_size / 4)))
                                                        real_size += 2;
                                                else
                                                        real_size += 3;
                                        } else
                                                real_size += 2;
                                }
                        }
                } else {
                        while (adjusted_pulse >= (2 * avg_size)) {
                                real_size += 4;
                                adjusted_pulse -= avg_size;
                        }
                        adjusted_pulse <<= 2;
                        while (adjusted_pulse >= ((avg_size * 3) + (avg_size / 4))) {
                                real_size += 2;
                                adjusted_pulse -= avg_size * 2;
                        }
                        if (adjusted_pulse >= ((avg_size * 2) + (avg_size / 4))) {
                                if (adjusted_pulse <= ((avg_size * 3) - (avg_size / 4))) {
                                        if (((adjusted_pulse >> 1) - adjust) < (avg_size + (avg_size / 4)))
                                                real_size += 2;
                                        else
                                                real_size += 3;
                                } else
                                        real_size += 3;
                        } else {
                                if (adjusted_pulse > ((avg_size * 2) - (avg_size / 4)))
                                        real_size += 2;
                                else {
                                        if (adjusted_pulse >= (avg_size + (avg_size / 4))) {
                                                if (((adjusted_pulse >> 1) - adjust) <= (avg_size - (avg_size / 4)))
                                                        real_size++;
                                                else
                                                        real_size += 2;
                                        } else
                                                real_size++;
                                }
                        }
                }

                /* after one pass to correctly initialize the average bitrate, outputs the bits */
                if (outstep == 1) {
                        for (j = real_size; j > 1; j--)
                                addbit(d, 0);
                        addbit(d, 1);
                        for (j = 0; j < real_size; j++)
                                *pt++ = (uae_u16)(pulse / real_size);
                }

                /* prepares for the next pulse */
                adjust = ((real_size * avg_size) / (4 << mfm)) - pulse;
                total -= psarray[array_index].size;
                totaldiv -= psarray[array_index].number_of_bits;
                psarray[array_index].size = pulse;
                psarray[array_index].number_of_bits = real_size;
                total += pulse;
                totaldiv += real_size;
                array_index++;
                if (array_index >= FDI_MAX_ARRAY)
                        array_index = 0;
        }

        fdi->out = bitoffset;
}

#endif

static void fdi2_celltiming(FDI *fdi, uint32_t totalavg, int bitoffset, uae_u16 *out) {
        uae_u16 *pt2, *pt;
        double avg_bit_len;
        int i;

        avg_bit_len = (double)totalavg / (double)bitoffset;
        pt2 = fdi->track_dst_buffer_timing;
        pt = out;
        for (i = 0; i < bitoffset / 8; i++) {
                double v = (pt2[0] + pt2[1] + pt2[2] + pt2[3] + pt2[4] + pt2[5] + pt2[6] + pt2[7]) / 8.0;
                v = 1000.0 * v / avg_bit_len;
                *pt++ = (uae_u16)v;
                pt2 += 8;
        }
        *pt++ = out[0];
        *pt = out[0];
}

static int decode_lowlevel_track(FDI *fdi, int track, struct fdi_cache *cache) {
        uae_u8 *p1;
        uae_u32 *p2;
        uae_u32 *avgp, *minp = 0, *maxp = 0;
        uae_u8 *idxp = 0;
        uae_u32 maxidx, totalavg, weakbits;
        int i, j, len, pulses, indexoffset;
        int avg_free, min_free = 0, max_free = 0, idx_free;
        int idx_off1 = 0, idx_off2 = 0, idx_off3 = 0;

        //	d = fdi->track_dst;
        p1 = fdi->track_src;
        pulses = get_u32(p1);
        if (!pulses)
                return -1;
        p1 += 4;
        len = 12;
        avgp = (uae_u32 *)fdi_decompress(pulses, p1 + 0, p1 + len, &avg_free);
        dumpstream(track, (uae_u8 *)avgp, pulses);
        len += get_u24(p1 + 0) & 0x3fffff;
        if (!avgp)
                return -1;
        if (get_u24(p1 + 3) && get_u24(p1 + 6)) {
                minp = (uae_u32 *)fdi_decompress(pulses, p1 + 3, p1 + len, &min_free);
                len += get_u24(p1 + 3) & 0x3fffff;
                maxp = (uae_u32 *)fdi_decompress(pulses, p1 + 6, p1 + len, &max_free);
                len += get_u24(p1 + 6) & 0x3fffff;
                /* Computes the real min and max values */
                for (i = 0; i < pulses; i++) {
                        maxp[i] = avgp[i] + minp[i] - maxp[i];
                        minp[i] = avgp[i] - minp[i];
                }
        } else {
                minp = avgp;
                maxp = avgp;
        }
        if (get_u24(p1 + 9)) {
                idx_off1 = 0;
                idx_off2 = 1;
                idx_off3 = 2;
                idxp = fdi_decompress(pulses, p1 + 9, p1 + len, &idx_free);
                if (idx_free) {
                        if (idxp[0] == 0 && idxp[1] == 0) {
                                idx_off1 = 2;
                                idx_off2 = 3;
                        } else {
                                idx_off1 = 1;
                                idx_off2 = 0;
                        }
                        idx_off3 = 4;
                }
        } else {
                idxp = fdi_malloc(pulses * 2);
                idx_free = 1;
                for (i = 0; i < pulses; i++) {
                        idxp[i * 2 + 0] = 2;
                        idxp[i * 2 + 1] = 0;
                }
                idxp[0] = 1;
                idxp[1] = 1;
        }

        maxidx = 0;
        indexoffset = 0;
        p1 = idxp;
        for (i = 0; i < pulses; i++) {
                if (p1[idx_off1] + p1[idx_off2] > maxidx)
                        maxidx = p1[idx_off1] + p1[idx_off2];
                p1 += idx_off3;
        }
        p1 = idxp;
        for (i = 0; (i < pulses) && (p1[idx_off2] != 0); i++) /* falling edge, replace with idx_off1 for rising edge */
                p1 += idx_off3;
        if (i < pulses) {
                j = i;
                do {
                        i++;
                        p1 += idx_off3;
                        if (i >= pulses) {
                                i = 0;
                                p1 = idxp;
                        }
                } while ((i != j) && (p1[idx_off2] == 0)); /* falling edge, replace with idx_off1 for rising edge */
                if (i != j)                                /* index pulse detected */
                {
                        while ((i != j) && (p1[idx_off1] > p1[idx_off2])) { /* falling edge, replace with "<" for rising edge */
                                i++;
                                p1 += idx_off3;
                                if (i >= pulses) {
                                        i = 0;
                                        p1 = idxp;
                                }
                        }
                        if (i != j)
                                indexoffset = i; /* index position detected */
                }
        }
        p1 = idxp;
        p2 = avgp;
        totalavg = 0;
        weakbits = 0;
        for (i = 0; i < pulses; i++) {
                int sum = p1[idx_off1] + p1[idx_off2];
                if (sum >= maxidx) {
                        totalavg += *p2;
                } else {
                        weakbits++;
                }
                p2++;
                p1 += idx_off3;
                idxp[i] = sum;
        }
        len = totalavg / 100000;
        outlog("totalavg=%u index=%d (%d) maxidx=%d weakbits=%d len=%d\n", totalavg, indexoffset, maxidx, weakbits, len);
        cache->avgp = avgp;
        cache->idxp = idxp;
        cache->minp = minp;
        cache->maxp = maxp;
        cache->avg_free = avg_free;
        cache->idx_free = idx_free;
        cache->min_free = min_free;
        cache->max_free = max_free;
        cache->totalavg = totalavg;
        cache->pulses = pulses;
        cache->maxidx = maxidx;
        cache->indexoffset = indexoffset;
        cache->weakbits = weakbits;
        cache->lowlevel = 1;

        return 1;
}

static unsigned char fdiid[] = {"Formatted Disk Image file"};
static int bit_rate_table[16] = {125, 150, 250, 300, 500, 1000};

void fdi2raw_header_free(FDI *fdi) {
        int i;

        fdi_free(fdi->mfmsync_buffer);
        fdi_free(fdi->track_src_buffer);
        fdi_free(fdi->track_dst_buffer);
        fdi_free(fdi->track_dst_buffer_timing);
        for (i = 0; i < MAX_TRACKS; i++) {
                struct fdi_cache *c = &fdi->cache[i];
                if (c->idx_free)
                        fdi_free(c->idxp);
                if (c->avg_free)
                        fdi_free(c->avgp);
                if (c->min_free)
                        fdi_free(c->minp);
                if (c->max_free)
                        fdi_free(c->maxp);
        }
        fdi_free(fdi);
        debuglog("FREE: memory allocated %d\n", fdi_allocated);
}

int fdi2raw_get_last_track(FDI *fdi) { return fdi->last_track; }

int fdi2raw_get_num_sector(FDI *fdi) {
        if (fdi->header[152] == 0x02)
                return 22;
        return 11;
}

int fdi2raw_get_last_head(FDI *fdi) { return fdi->last_head; }

int fdi2raw_get_rotation(FDI *fdi) { return fdi->rotation_speed; }

int fdi2raw_get_bit_rate(FDI *fdi) { return fdi->bit_rate; }

int fdi2raw_get_type(FDI *fdi) { return fdi->disk_type; }

int fdi2raw_get_write_protect(FDI *fdi) { return fdi->write_protect; }

FDI *fdi2raw_header(FILE *f) {
        int i, offset, oldseek;
        uae_u8 type, size;
        FDI *fdi;

        debuglog("ALLOC: memory allocated %d\n", fdi_allocated);
        fdi = fdi_malloc(sizeof(FDI));
        memset(fdi, 0, sizeof(FDI));
        fdi->file = f;
        oldseek = ftell(fdi->file);
        fseek(fdi->file, 0, SEEK_SET);
        fread(fdi->header, 2048, 1, fdi->file);
        fseek(fdi->file, oldseek, SEEK_SET);
        if (memcmp(fdiid, fdi->header, strlen((char *)fdiid))) {
                fdi_free(fdi);
                return NULL;
        }
        if ((fdi->header[140] != 1 && fdi->header[140] != 2) ||
            (fdi->header[141] != 0 && !(fdi->header[140] == 2 && fdi->header[141] == 1))) {
                fdi_free(fdi);
                return NULL;
        }

        fdi->mfmsync_buffer = fdi_malloc(MAX_MFM_SYNC_BUFFER * sizeof(int));
        fdi->track_src_buffer = fdi_malloc(MAX_SRC_BUFFER);
        fdi->track_dst_buffer = fdi_malloc(MAX_DST_BUFFER);
        fdi->track_dst_buffer_timing = fdi_malloc(MAX_TIMING_BUFFER);

        fdi->last_track = ((fdi->header[142] << 8) + fdi->header[143]) + 1;
        fdi->last_track *= fdi->header[144] + 1;
        if (fdi->last_track > MAX_TRACKS)
                fdi->last_track = MAX_TRACKS;
        fdi->last_head = fdi->header[144];
        fdi->disk_type = fdi->header[145];
        fdi->rotation_speed = fdi->header[146] + 128;
        fdi->write_protect = fdi->header[147] & 1;
        outlog("FDI version %d.%d\n", fdi->header[140], fdi->header[141]);
        outlog("last_track=%d rotation_speed=%d\n", fdi->last_track, fdi->rotation_speed);

        offset = 512;
        i = fdi->last_track;
        if (i > 180) {
                offset += 512;
                i -= 180;
                while (i > 256) {
                        offset += 512;
                        i -= 256;
                }
        }
        for (i = 0; i < fdi->last_track; i++) {
                fdi->track_offsets[i] = offset;
                type = fdi->header[152 + i * 2];
                size = fdi->header[152 + i * 2 + 1];
                if (type == 1)
                        offset += (size & 15) * 512;
                else if ((type & 0xc0) == 0x80)
                        offset += (((type & 0x3f) << 8) | size) * 256;
                else
                        offset += size * 256;
        }
        fdi->track_offsets[i] = offset;

        return fdi;
}

int fdi2raw_loadrevolution_2(FDI *fdi, uae_u16 *mfmbuf, uae_u16 *tracktiming, int track, int *tracklength, int *indexoffsetp,
                             int *multirev, int mfm) {
        struct fdi_cache *cache = &fdi->cache[track];
        int len, i, idx;

        memset(fdi->track_dst_buffer, 0, MAX_DST_BUFFER);
        idx = cache->indexoffset;
        fdi2_decode(fdi, cache->totalavg, cache->avgp, cache->minp, cache->maxp, cache->idxp, cache->maxidx, &idx, cache->pulses,
                    mfm);
        // fdi2_gcr_decode (fdi, totalavg, avgp, minp, maxp, idxp, idx_off1, idx_off2, idx_off3, maxidx, pulses);
        outlog("track %d: nbits=%d avg len=%.2f weakbits=%d idx=%d\n", track, bitoffset, (double)cache->totalavg / bitoffset,
               cache->weakbits, cache->indexoffset);
        len = fdi->out;
        if (cache->weakbits >= 10 && multirev)
                *multirev = 1;
        *tracklength = len;

        for (i = 0; i < (len + 15) / (2 * 8); i++) {
                uae_u8 *data = fdi->track_dst_buffer + i * 2;
                *mfmbuf++ = 256 * *data + *(data + 1);
        }
        fdi2_celltiming(fdi, cache->totalavg, len, tracktiming);
        if (indexoffsetp)
                *indexoffsetp = idx;
        return 1;
}

int fdi2raw_loadrevolution(FDI *fdi, uae_u16 *mfmbuf, uae_u16 *tracktiming, int track, int *tracklength, int mfm) {
        return fdi2raw_loadrevolution_2(fdi, mfmbuf, tracktiming, track, tracklength, 0, 0, mfm);
}

int fdi2raw_loadtrack(FDI *fdi, uae_u16 *mfmbuf, uae_u16 *tracktiming, int track, int *tracklength, int *indexoffsetp,
                      int *multirev, int mfm) {
        uae_u8 *p;
        int outlen, i;
        struct fdi_cache *cache = &fdi->cache[track];

        if (cache->lowlevel)
                return fdi2raw_loadrevolution_2(fdi, mfmbuf, tracktiming, track, tracklength, indexoffsetp, multirev, mfm);

        fdi->err = 0;
        fdi->track_src_len = fdi->track_offsets[track + 1] - fdi->track_offsets[track];
        fseek(fdi->file, fdi->track_offsets[track], SEEK_SET);
        fread(fdi->track_src_buffer, fdi->track_src_len, 1, fdi->file);
        memset(fdi->track_dst_buffer, 0, MAX_DST_BUFFER);
        fdi->track_dst_buffer_timing[0] = 0;

        fdi->current_track = track;
        fdi->track_src = fdi->track_src_buffer;
        fdi->track_dst = fdi->track_dst_buffer;
        p = fdi->header + 152 + fdi->current_track * 2;
        fdi->track_type = *p++;
        fdi->track_len = *p++;
        fdi->bit_rate = 0;
        fdi->out = 0;
        fdi->mfmsync_offset = 0;

        if ((fdi->track_type & 0xf0) == 0xf0 || (fdi->track_type & 0xf0) == 0xe0)
                fdi->bit_rate = bit_rate_table[fdi->track_type & 0x0f];
        else
                fdi->bit_rate = 250;

        outlog("track %d: srclen: %d track_type: %02.2X, bitrate: %d\n", fdi->current_track, fdi->track_src_len, fdi->track_type,
               fdi->bit_rate);

        if ((fdi->track_type & 0xc0) == 0x80) {

                outlen = decode_lowlevel_track(fdi, track, cache);

        } else if ((fdi->track_type & 0xf0) == 0xf0) {

                outlen = decode_raw_track(fdi);

        } else if ((fdi->track_type & 0xf0) == 0xe0) {

                outlen = handle_sectors_described_track(fdi);

        } else if ((fdi->track_type & 0xf0)) {

                zxx(fdi);
                outlen = -1;

        } else if (fdi->track_type < 0x10) {

                decode_normal_track[fdi->track_type](fdi);
                fix_mfm_sync(fdi);
                outlen = fdi->out;

        } else {

                zxx(fdi);
                outlen = -1;
        }

        //	amiga_check_track (fdi);

        if (fdi->err)
                return 0;

        if (outlen > 0) {
                if (cache->lowlevel)
                        return fdi2raw_loadrevolution_2(fdi, mfmbuf, tracktiming, track, tracklength, indexoffsetp, multirev,
                                                        mfm);
                *tracklength = fdi->out;
                for (i = 0; i < ((*tracklength) + 15) / (2 * 8); i++) {
                        uae_u8 *data = fdi->track_dst_buffer + i * 2;
                        *mfmbuf++ = 256 * *data + *(data + 1);
                }
        }
        return outlen;
}
